Flexible lens mount system for rapid tilt photography

ABSTRACT

The disclosure generally relates to photography, including both still photography and video photography. One aspect of the invention is directed toward a lens system that includes a lens, a fitting mountable to a camera, and a flexible body extending between the lens and the fitting. The fitting can be the sole support for the body relative to the camera. The body can be configured to position the lens among at least two operative positions relative to the camera when the fitting is mounted to the camera.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a continuation of U.S. application Ser. No.12/859,739, filed Aug. 19, 2010, and currently pending, which is acontinuation of U.S. National Phase Application No. 10/571,151, filedMar. 9, 2006, based on International Application No. PCT/US2004/033141,filed Oct. 7, 2004, which claims the benefit of U.S. Provisional PatentApplication No. 60/509,368, filed Oct. 7, 2003, all of which areincorporated herein by reference.

TECHNICAL FIELD

This disclosure generally relates to photography, including both stillphotography, video photography, and motion film photography. In someembodiments, the invention provides flexible lens systems that areparticularly well-suited for rapid snapshots, e.g., with a digitalcamera.

BACKGROUND

Upon photographing a large surface, the entirety of the object to betaken cannot always fit within a field of focus. In such a case, theclose and/or distant portion(s) of the object become out of focus.Photographers can expand the area in focus with an adapter having a tiltmechanism, typically a tilt/shift lens, that tilts the photographic lensrelative to the camera body. Unfortunately, most existing tilt and shiftlenses are precision instruments that employ precisely adjustedmechanical controls to focus the lens and to adjust the angle of thelens relative to the image capture plane (which may be film or a digitalsensor, depending on the type of camera).

The precise control may be useful for some controlled settings instudios, but can significantly complicate photography in the field. Thegeneral perception of tilt/shift lenses is that they are cumbersome touse, slow to operate, demand tripod use, and can require manual, insteadof automatic, exposure modes. Conventional tilt/shift lenses arerelatively heavy, as well, further limiting their practical use. Theselenses are also quite expensive, with most commercial tilt/shift lensescosting well in excess of US$1,000.

Some photographers also use bellows cameras to achieve photographiceffects. For example, such cameras may be used to produce artisticeffects, such as soft focus images wherein a portion of the image may bein sharp focus but a peripheral region may be out of focus. Many bellowscameras rely on heavy, cumbersome rails that protrude from the bottom ofthe camera to guide the lens as it moves in and out relative to thecamera body. This added weight and mechanical complexity has largelylimited bellows cameras to studio photography.

Many digital cameras are significantly smaller and lighter than moreconventional 35 mm cameras. As a result, many digital cameras aregenerally considered more easily transportable, e.g., in a pocketinstead of a large camera bag, and convenient for spontaneousphotographs. The heavy, bulky nature of conventional tilt/shift lensesand bellows lenses is incompatible with the convenience and freedomafforded by digital cameras.

Embodiments of the invention address these and other limitations of theprior art.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top plan view schematically illustrating a camera systemhaving a lens system and an optical device in accordance with anembodiment of the invention.

FIG. 2 is a top plan view of the lens system in FIG. 1.

FIG. 3 is a rear view of the lens system of FIG. 2.

FIG. 4 is a side view, in partial cross section (taken along line 4-4 inFIG. 3), of the lens system of FIGS. 2 and 3.

FIG. 5 is a front view of the lens system of FIGS. 2-4.

FIG. 6 is a top plan view schematically illustrating movement of thelens system of FIGS. 2-5 in accordance with one embodiment of theinvention.

FIG. 7 is a top cross-sectional schematic illustration of the camerasystem shown in FIG. 1 with the optical device removed and showing animage capture plane.

FIG. 8A is a partially schematic illustration of the camera system shownin FIG. 7 photographing a series of objects that are oblique to thecamera body.

FIG. 8B is a partially schematic illustration the camera system in FIG.8A photographing a series of objects from a different orientation thanthe one shown in FIG. 8A.

FIG. 8C is a partially schematic illustration of the camera system inFIG. 8A photographing a series of objects from a different orientationthan the ones shown in FIGS. 8A and 8B.

FIG. 9A is a partially schematic illustration of a camera system havinga lens body with at least two focusing collars in accordance withanother embodiment of the invention.

FIG. 9B is a partially schematic illustration of the camera system shownin FIG. 9A wherein at least a portion of the body is being compressed.

FIG. 9C is a partially schematic illustration of the camera system shownin FIG. 9A wherein at least a portion of the body is being compressedand the body is being bent to one side.

FIG. 9D is a partially schematic illustration of the camera system shownin FIG. 9A wherein an operator is bending the body to one side byapplying an extending force to a first focusing collar and a compressingforce to a second focusing collar.

FIG. 10 is a chart containing process portions for a method of adjustingfocus of a camera using a lens assembly in accordance with an embodimentof the invention.

FIG. 11 is a chart containing process portions for a method of adjustingfocus of a camera using a lens assembly in accordance with anotherembodiment of the invention.

DETAILED DESCRIPTION

A. Overview

Various embodiments of the present invention provide flexible lenssystems and camera systems employing flexible lens mounts. Except wherecontext dictates otherwise, the term “lens” is used throughout toinclude both a single lens and a set of lenses and the term“photography” is used throughout to include both still and videophotography accomplished using a camera system (e.g., a conventional 35mm camera, a digital camera, and/or a video camera or recorder).Similarly, except where context dictates otherwise, the term photographis used throughout to include one or more images produced, at least inpart, by a camera system (e.g., conventional photograph(s), digitalimage(s), video recording(s), and/or motion film photography). Thefollowing description provides specific details of certain embodimentsof the invention illustrated in the drawings to provide a thoroughunderstanding of those embodiments. It should be recognized, however,that the present invention can be reflected in additional embodimentsand the invention may be practiced without some of the details in thefollowing description.

One aspect of the invention is directed toward a lens system thatincludes a lens, a fitting mountable to a camera, and a resilientlyflexible body extending between the lens and the fitting. The fittingcan be the sole support for the body relative to the camera. The bodycan be configured to position the lens among at least two operativepositions relative to the camera when the fitting is mounted to thecamera. If so desired, the body can have a rest position to which it atleast approximately returns after being moved away from the restposition and released.

A lens system in accordance with another embodiment of the inventionincludes a lens, a fitting that is mountable to a camera, and a flexiblebody that extends between the lens and the fitting. The fitting is thesole support for the body relative to the camera. The body is configuredto selectively retain any one of a plurality of discrete configurations,each of which positions the lens differently relative to the fitting.

Another embodiment of the invention provides a lens system that includesa lens, a fitting mountable to a camera, a flexible body extendingbetween the lens and the fitting, and a lens support. The fitting is thesole support for the body relative to the camera. The body is configuredto position the lens among at least two operative positions relative tothe camera when the fitting is mounted to the camera; the body includesa tubular segment. The lens is coupled to the body by the lens support.At least one portion of the lens support is received by the tubularsegment of the body and is movable relative to at least a portion of thetubular segment of the body.

One further embodiment of the invention relates to a method foradjusting focus of a camera using a lens assembly. In accordance withthis method, the lens assembly is attached to a camera with a fittingthat serves as a sole support for a body of a lens assembly relative tothe camera. The lens assembly is reconfigured from a first configurationto a second configuration by manually flexing the body of the lensassembly. A lens of the lens assembly has a first operative positionrelative to the camera in the first configuration and a different secondoperative position relative to the camera in the second configuration.

Yet another embodiment of the invention provides a method ofphotographing a subject that includes orienting a camera with respect tothe subject. The camera has a lens system that includes a fitting, alens, and a tubular, resiliently flexible body extending between thefitting and the lens. A length of at least a portion of the body ismanually adjusted by acting against a restoring force of the resilientlyflexible body, thereby adjusting focus. The method may further includetaking at least one photograph with the adjusted focus.

For ease of understanding, the following discussion is broken down intotwo areas of emphasis. The first section discusses various flexible lenssystems and camera systems employing flexible lens systems in accordancewith embodiments of the invention. The second section outlines methodsof taking photographic images in accordance with other embodiments ofthe invention.

B. Flexible Lens Systems and Camera Systems Employing Flexible LensSystems

FIGS. 1-6 schematically illustrate a camera system 10 and a lens system100 in accordance with embodiments of the invention. The camera system10 (FIG. 1) generally includes the lens system 100 coupled to a camerabody or camera 12. The camera 12 may be any conventional still or videocamera. In one embodiment, the camera 12 comprises a 35 millimetercamera, e.g., a 35 millimeter SLR camera. In other embodiments, thecamera 12 can include a larger or smaller format camera (e.g., a camerawith a larger or smaller lens and/or image capture size). In one usefulembodiment of the invention, the camera 12 comprises a digital camerahaving a suitable display (not shown) for viewing an image captured bythe camera, as is conventional in the art.

Also in FIG. 1, an optical device 160 (e.g., a filter or conversionlens) for providing various optical affects (e.g., softening aphotographic image) is coupled to the lens system 100. The opticaldevice 160 and the lens system 100 can be configured so that the opticaldevice 160 is releasably coupled to the lens system 100 opposite fromwhere the lens system 100 couples to the camera 12. In otherembodiments, the optical device 160 can be permanently attached to thelens system 100. In still other embodiments of the invention, an opticaldevice 160 is not used.

FIGS. 2-5 illustrate aspects of a lens system 100 in accordance with oneembodiment of the invention. The lens system 100 includes a camera mountor fitting 110, a flexible body 120, and a lens assembly 130 (FIGS.3-5). The camera mount 110 may be a plastic or aluminum mount of thetype commonly used to mount a lens to a camera. The mounting system maydiffer from one camera to another, e.g., from a Canon to a Minolta, butthe camera mount 110 is easily adaptable for use with a wide variety ofcamera bodies 12. In certain useful embodiments, the fitting 110 can bethe sole support for the lens system 100 relative to the camera 12.

The flexible body 120 of the lens system 100 is coupled to the cameramount 110 adjacent to an end of the body 120. This permits the cameramount 110 to effectively attach the lens body 120 to the camera 12. Thelens body 120 may be formed of a flexible tubular material. In theillustrated embodiment, the tubular material is generally circular incross section. In other embodiments, the tubular body 120 may have across section that is not circular, e.g., ovoid, square, hexagonal, orany other suitable polyhedral shape. The length and transversedimensions of the lens body 120 can be varied as desired (e.g., fordifferent uses and/or different camera formats). Smaller bodies 120 willgenerally be lighter and more flexible than a larger body 120 formed ofthe same material. However, a body 120 having a larger transversedimension (e.g., diameter in the illustrated embodiment) allows greaterlight capture and facilitates use of better quality lenses 134(discussed below).

The body 120 should be sufficiently stiff to support the lens assembly130 with respect to the camera 12, yet allow a user to flex the body 120in a desired direction with relative ease. This feature can allow theuser to move the body 120 and lens assembly 130 to various operativepositions (e.g., positions where a photograph can be taken) to obtainvarious focusing effects. This is facilitated in the illustratedembodiment by forming the body 120 from a flexible polymeric materialwith a series of compressible ridges that can compress and/or expand asthe body 120 is moved.

For example, one side of the body 120 can be compressed and an oppositeside of the body 120 can be expanded to move the body and lens assembly130 left or right as indicated by arrows M_(L) and M_(R) (shown in FIG.2). The body 120 can be flexed up or down in a similar manner. The body120 can also be compressed in the direction of arrow M_(C) (shown inFIG. 2), shortening its length and moving the lens assembly 130 closerto the camera 12 (shown in FIG. 1), without materially changing thediameter of the body 120. Similarly, the body 120 can be expanded in thedirection of arrow M_(E) (shown in FIG. 2), lengthening the body 120 andmoving the lens assembly 130 away from the camera 12 (shown in FIG. 1).Other embodiments can include other arrangements, for example, a body120 that can be compressed, but not expanded; a body made from adifferent type of material (e.g., a composite), and/or a body withoutridges. In still further embodiments, at least a portion of the flexiblebody 120 is formed from a rigid material and at least a portion of thebody 120 is formed from a flexible material.

In the illustrated embodiment, the body 120 tends to resiliently returntoward a rest position, which may be approximately perpendicular to thecamera body 12 (FIG. 1), after removing (a) bending, compressing, and/orextending force(s). Accordingly, the bending, compressing, and/orextending force(s) must be maintained to hold the body 120 and lensassembly 130 in a selected operative position relative to the body ofthe camera 12.

In another embodiment, the body 120 can hold a selected position once itis moved to a selected position (e.g., the body 120 and lens assembly130 can be placed in multiple operative positions). For example, theridges can be configured to operate like the ridges on a bendabledrinking straw and hold the body and lens assembly in the position inwhich they are placed by a user. In such an implementation, the body canselectively retain any one of a plurality of discrete configurations byselectively collapsing portions of at least some of the ridges, much inthe same way that a bendable drinking straw can be bent betweendifferent configurations and retain each of those configurations. Eachone of these configurations positions the lens 130 in a differentoperative position relative to the body of the camera 12 and the fitting110.

Turning to FIGS. 3-5, the lens assembly 130 generally includes a lenssupport 132, a lens 134, and an aperture or f-stop 136. In theillustrated embodiment, the lens 134 is spaced rearwardly from the frontend of the body 120 by the lens support 132. To permit easy flexure ofthe body 120, the lens support 132 may have a smaller dimension adjacentthe lens than forwardly where it is attached to the body 120, allowingat least a portion of the lens support 132 to move relative to a portionof the body 120. In the particular embodiment shown in FIG. 4, thesupport 132 is generally frustoconical. Other embodiments can have otherarrangements, for example, the lens 134 can be mounted directly to thebody. As discussed above, the lens 134, shown schematically in FIG. 4,can include a single lens or multiple lenses that are closely spacedtogether. In other embodiments, the body can support multiple lensesseparated by a larger distance.

In the illustrated embodiment, the f-stop is a fixed aperture thatcontrols how much light passes through the body 120 to the camera in aselected increment of time. In other embodiments, the f-stop can bereplaceable, e.g., it may be a removable disk with an aperture that canbe replaced by another disk having a differently sized aperture. Instill other embodiments, the f-stop can be adjustable. For example, thef-stop can include a series of overlapping blades that can be moved oradjusted relative to each other to form different size apertures,similar to the f-stop used on current lenses. In yet other embodiments,the lens support 132 and/or the lens body 120 can form or act as anf-stop, controlling the volume of light that passes through the body 120to the camera 12.

In one embodiment, a user may simply grasp the body 120 to manipulate orbend it. In the illustrated embodiment, a focusing collar 140 is carriedby the body 120 adjacent its distal end. The illustrated focusing collar140 is generally annular in shape, though other suitable shapes, e.g.,square, may be used. Instead of a continuous collar, as shown, thefocusing collar 140 may comprise a series of laterally outwardlyextending flanges spaced at a fixed location about the periphery of thebody 120. The focusing collar 140 may be formed of plastic, metal (e.g.,aluminum), or any other suitable material.

As suggested in FIG. 6, the body 120 of the lens system 100 can beflexed by manually engaging the focusing collar 140, e.g., with a finger150, and applying a force F adjacent a side of the focusing collar 140.This will tend to compress the body 120 on one lateral side and may alsostretch or extend the body 120 on the other lateral side, moving thebody 120 and lens assembly 130 (shown in FIG. 4) as indicated by arrowM_(L). This can have the effect of moving one portion (e.g., side oredge) of the lens 134 toward the camera 12 and another portion (e.g., anopposite side or edge) away from the camera. The center of the lens 134can also move relative to the camera 12. The angle θ through which thebody 120 can be flexed can vary significantly depending on the relativedimensions and flexibility of the body 120 and the relative dimensionsand positions of the lens 134 and f-stop aperture 136 within the body120. In one embodiment, the angle θ may be 90° or more. As discussedabove, in certain embodiments, the body 120 can be manually extended orcompressed to move the lens 134 away from or toward the camera 12,respectively.

The very simple design of the lens system 100 shown in FIGS. 1-6 allowslens systems in accordance with embodiments of the invention to beappreciably smaller and lighter than conventional tilt/shift cameralenses on the market today. By employing a relatively lightweight body120 that has sufficient stiffness to support the lens assembly 130 withrespect to the camera, the rails commonly required to support bellowslenses can be eliminated. Accordingly, lens systems 100 in accordancewith certain embodiments of the invention can be quickly positioned toallow rapid operation with reduced weight as compared to the complex,finely-machined adjusting mechanisms of tilt/shift lenses. This isparticularly convenient in the case of digital photography, which tendsto emphasize reduced size, reduced weight, and simple, point-and-clickphotographic capability. The mechanical simplicity of the lens system100 also allows it to be manufactured much less expensively thanconventional tilt/shift lenses, permitting sale to a wide range ofconsumers instead of the limited appeal of conventional tilt/shiftlenses to professional photographers or avid hobbyists.

C. Methods of Taking Photographic Images

As noted above, other embodiments of the invention provide methods oftaking photographic images. In the following discussion, reference ismade to camera system 10 of FIG. 1, and the particular flexible lenssystem 100 illustrated in FIGS. 2-6. It should be understood, though,that reference to these particular systems is solely for purposes ofillustration and that the methods outlined below are not limited to anyparticular camera system or lens system shown in the drawings ordiscussed in detail above.

The camera system 10 with its lens system 100 can allow a photographerto achieve special focusing effects in a pliable, enjoyable to use,spontaneous fashion, in contrast to a cumbersome, hard-to-adjusttilt/shift lens, bellows camera, or perspective control lens. Asdiscussed above, the lens system 100 can also be lighter, smaller, andeasier to manufacture than previous or existing lenses.

The lens system 100 allows a photographer, while shooting photographs ofactive or inactive subjects, to use his or her finger(s) to manipulatefreely and easily the lens angle and/or lens location relative to theimage capture plane 14, shown in FIG. 7, to focus the camera system 10.Changing the lens angle and/or lens location relative to the camera 12controls how light hits the image capture plane 14 (e.g., film ordigital sensor). For example, in FIG. 7, the light reflected from pointA (e.g., a subject) enters the camera and impacts the image captureplane at point B so that the image or subject will generally be in sharpfocus. If desired, a user can focus the lens system 100 by positioningthe body 120 so that a portion of the light reflected from point Aenters the camera and is dispersed when it contacts the image captureplane 14 so that at least a portion of the image is not in sharp focus(e.g., the image is softer and/or blurred). Additionally, as point Amoves relative to the camera, the user can focus the lens system 100 bymoving the body to keep the image in sharp focus or to make at least aportion of the image softer.

The user may focus the camera system 10 by manually moving the lensassembly 130 in and out relative to the camera 12, and/or bending thebody 120 in any direction relative to the camera body 12. Moving thelens assembly 130 away from the camera 12 (e.g., extending the body 120)allows the lens 134 to bring objects that are close to the camera intosharp focus. Compressing the body 120 moves the lens assembly 130 towardthe camera, allowing the lens 134 to bring objects that are further awayfrom the camera into sharp focus and/or allowing the lens 134 to focusat infinity.

The user can also change the area of the picture plane that is generallyin sharp focus by pulling or extending a portion of the body 120. Forexample, in certain situations, the user can pull one point on thefocusing collar 140 toward the camera, which causes the body 120 to bendup, down, left, or right. Correspondingly, the lens 134 within the body120 moves relative to the camera 12 and can tilt up, down, left, orright. This can cause certain portions of the image or subject to comeinto sharp focus and other portions to the image to be softer orblurred. In other situations, bending the body 120 can cause a subjectthat is at an oblique angle to the camera 12 to be entirely in sharpfocus.

One aspect of this operation is known in the art as the “Scheimpflugeffect,” which allows you to increase effective depth-of-field simply bytilting the camera lens along its axis in the direction of the imageplane. This technique of sharpness distribution control, which isnormally only possible with the swing and tilt movements of aconventional tilt/shift lenses, allows you to align the lens with anysubject plane without changing the camera position or stopping down thelens (e.g., reducing the f-stop). This means that you can use a wideraperture and a faster shutter speed, reducing or eliminating the risk ofcamera shake or blur due to subject movement, or simply have greateroverall depth-of-field for a given aperture. Additionally, this sameprinciple can allow a photographer to intentionally soften or blurportions of the image to achieve more creative, photojournalistic-stylecompositions.

FIG. 8A is a partially schematic illustration of the camera system shownin

FIG. 7 photographing a series of objects that are at an oblique angle tothe camera body 12. The lens system 100 is approximately perpendicularto the camera body 12 and the focus area 180 where objects willgenerally be in sharp focus is depicted by the area enclosed by dashedlines. Those objects 170 that are within the focus area 180 willgenerally appear to be in sharp focus. Those objects 170 that are not inthe focus area 180 will not appear to be in sharp focus and can appearsofter and/or blurred. The further away an object 170 is from the focusarea 180, the softer or more blurred its image can appear. The focusarea 180 can be moved by compressing, extending, and/or bending the lensbody 120 of the lens system 100. For example, by compressing the body,the focus area 180 can be moved away from the camera.

The shape and/or orientation of the focus area relative to the camerabody 12 can also be adjusted, as shown in FIGS. 8B and 8C. In FIGS. 8Band 8C the camera body 12 has been placed at different angles relativeto a series of objects 170. The body 120 of the lens system 100 has beenbent toward the objects so that the focus area 180 (shown in dashedlines) includes all of the objects 170. Accordingly, all the objects 170will appear to be in generally sharp focus even though they are atvarying distances from the camera 12. The user intuitively knows whenthis point is reached because the image in the camera viewfinder appearsin focus from close range to distant range (e.g., all the objects appearto be in sharp focus). This feature/principle can also be used to movethe focus area 180 so that certain objects 170 are not in sharp focus(e.g., are not in the focus area 180).

To facilitate focusing the camera, in certain embodiments, multiplefocusing collars 140 can be coupled to the lens body 120. For example,the camera system 10 in FIG. 9A includes a lens system 100 having aflexible body 120 with two focusing collars 140, shown as a firstfocusing collar 140 a and a second focusing collar 140 b. Otherarrangements can have more or fewer focusing collars 140. When the lenssystem 100 is attached to the camera 12 the focusing collars 140 can beused by an operator to manipulate the lens body to focus the camerasystem. For example, as shown in FIG. 9B, the operator can apply acompressing force (shown as F_(C)) to both sides of the second focusingcollar 140 b with the bottoms of the operator's fingers to compress atleast a portion of the lens body 120 to focus the camera system 10.Similarly, the operator can apply an extending force (opposite thecompressing force) to both sides of the first focusing collar 140 a withthe tops of the operator's fingers to extend at least a portion of thelens body 120.

As shown in FIG. 9C, the operator can also bend the body 120 by applyinga compressing force (shown as F_(C1)) to one side (e.g., the left side)of the second focusing collar 140 b with the bottom(s) of the operator'sfinger(s) and a lesser compressing force (shown as F_(C2)) to the otherside (e.g., the right side) of the second focusing collar 140 b tocompress at least a portion of the lens body 120. This will have theeffect of compressing and bending one or more portions of the body 120and can move the lens 134 (not shown in FIG. 9C) toward the camera 12and tilt the lens 134 relative to the camera 12 (or the associated imagecapture plane) to achieve a desired focusing effect. As shown in FIG.9D, the operator can also apply an extending force (shown as F_(E)) tothe first focusing collar 140 a with the top(s) of the operator'sfinger(s) and a compressing force (shown as F_(E)) to the secondfocusing collar 140 b to bend the lens body 120 and focus the camerasystem 10. It will be recognized that these combinations of compressing,extending, and/or bending the body 120 have been provided forillustrative purposes only and that various other combinations can beused. For example, an operator can also apply an extending force to oneside of the first focusing collar 140 a and a lesser extending force toanother side of the first focusing collar 140 a to move the lens 134(not shown) away from the camera 12 and to tilt the lens 134 relative tothe camera 12 (or image capture plane) to achieve a desired focusingeffect.

As discussed above, these focusing features (e.g., compressing,extending, and/or bending the body 120) can allow the photographer toachieve two effects: (1) controlling a ‘sweet spot’ within the pictureplane where the image is in sharp focus, with surrounding areas of theimage at the same depth of field remaining less sharp or blurred; and(2) photographing a horizontal surface from an oblique point of view,effectively making the whole of that surface the principal plane ofsharp focus. The benefit of the sweet-spot focusing effect is to allowthe photographer to heighten the interest in a particular area of thephoto and increase creative interest, without the time and effort ofusing image-processing software, such as Adobe® Photoshop®.Additionally, the sweet-spot focusing effect can allow a photographer toadd real-time creativity to photographs and/or achieve results thatwould be difficult or impossible to achieve after the fact withimage-processing software. The benefit of the tilt focusing effect is toallow a plane that is in an oblique angle to the image capture surfacebe entirely in focus rather than just partly in focus, without resortingto very low f-stops, which actually decrease the amount of light andtherefore increase the risk of undesired blurring. Another benefit ofcertain embodiments described above is that methods of adjusting the‘sweet spot’ of focus or the tilt of the lens 134 allows a much morefluid and continuously adjustable arrangement of the photo, enablingmore spontaneous shots and more creative, photojournalistic-stylecompositions than are possible using traditional tilt-shift lenses thattake a long time to properly align and/or using image-processingsoftware.

Accordingly, FIG. 10 includes various method steps for adjusting focusof a camera in accordance with embodiments of the invention and FIG. 11includes various method steps for photographing a subject in accordancewith embodiments of the invention. In FIG. 10, a method for adjustingfocus of a camera using a lens assembly 1000 can include attaching thelens system to the camera with a fitting that serves as a sole supportfor a body of the lens assembly relative to the camera (process portion1002). The process can further include reconfiguring the lens assemblyfrom a first configuration to a second configuration by manually flexingthe body of the lens assembly (process portion 1004). A lens of the lensassembly can have a first operative position relative to the camera inthe first configuration and a different second operative positionrelative to the camera in the second configuration (process portion1004).

In certain embodiments, the method can further include manuallyrestraining the body to retain the lens assembly in the secondconfiguration for taking a photograph (process portion 1006). In otherembodiments the lens can be coupled to the body by a lens support(process portion 1008). In still other embodiments, the body can be in arest position in the first configuration and reconfiguring the lensassembly can include manually flexing the body away from the restposition (process portion 1010). The method can further includereconfiguring the assembly from the second configuration to the firstconfiguration by allowing the body to resiliently substantially returnto the rest position (process portion 1010). In yet another embodiment,the lens system can substantially retain the second configuration afterthe body is manually flexed and released (process portion 1012). Stillfurther embodiments, manually flexing the body can include moving atleast one portion of the lens closer to the camera and/or at least oneportion of the lens away from the camera (process portion 1014). In yetanother embodiment, manually flexing the body can include moving a firstlateral edge or portion of the lens away from the camera and an oppositesecond lateral edge or portion of the lens towards the camera (processportion 1016).

In FIG. 11, a method for photographing a subject 1100 can includeorienting a camera with respect to the subject (process portion 1102).The camera can have a lens system that includes a fitting, a lens, and atubular, resiliently flexible body extending between the fitting and thelens (process portion 1102). The method can further include manuallyadjusting a length of at least a portion of the body by acting against arestoring force of the resiliently flexible body, thereby adjustingfocus (process portion 1104). The method can still further includetaking at least one photograph (process portion 1106).

In certain embodiments, manually adjusting a length of at least aportion of the body can include compressing a first side or portion ofthe body and extending a second side or portion of the body (processportion 1108). In other embodiments, manually adjusting a length of atleast a portion of the body includes at least one of compressing a firstportion of the body to move a first portion of the lens toward thecamera and extending a second portion of the body to move a secondportion of the lens away from the camera (process portion 1110). Instill other embodiments, taking at least one photograph can include atleast one of taking multiple photographs and taking video photography(process portion 1112).

A feature of certain embodiments described above is that a lens systemwith a fluidly and rapidly adjustable focus can be provided.Additionally, the lens can be inexpensive, light weight, and intuitiveand easy to use. An advantage of this feature is that it can provide aphotographer with the ability to rapidly take a series of photographsand to vary the images in an aesthetically pleasing manner. This can beadvantageous to cameras using conventional film, digital cameras, andvideo cameras.

Digital photography has become increasingly popular in recent years,with sales of digital single lens reflex camera increasing 100% in 2002and digital camera sales eclipsing film camera sales in 2003. Aspects ofdigital photography are significantly different from film photography.For example, single lens reflex digital cameras can offer nearlyimmediate feedback on the quality of a photograph just taken bydisplaying the image in a liquid crystal display on the camera body 12.This gives photographers using digital single reflex cameras very fastfeedback on the look of a photograph before any developing expense hasoccurred, dramatically reducing the time and expense necessary to see aphotographic image. Lens systems in accordance with certain embodimentsdescribed above can be well suited to allow digital camera users to takeadvantage of these digital camera features by allowing a photographer toexperiment with a composition by taking a series of shots over a shortperiod of time until finding an aesthetically pleasing result.

The above-detailed embodiments of the invention are not intended to beexhaustive or to limit the invention to the precise form disclosedabove. Specific embodiments of, and examples for, the invention aredescribed above for illustrative purposes, but those skilled in therelevant art will recognize that various equivalent modifications arepossible within the scope of the invention. For example, whereas stepsare presented in a given order, alternative embodiments may performsteps in a different order. The various embodiments described herein canbe combined to provide further embodiments.

Unless the context clearly requires otherwise, throughout thedescription and the claims, the words “comprise,” “comprising,” and thelike are to be construed in an inclusive sense as opposed to anexclusive or exhaustive sense, i.e., in a sense of “including, but notlimited to.” Additionally, the words “herein,” “above,” “below,” andwords of similar import, when used in this application, shall refer tothis application as a whole and not to any particular portions of thisapplication. Use of the word “or” in reference to a list of items isintended to cover a) any of the items in the list, b) all of the itemsin the list, and c) any combination of the items in the list.

In general, the terms used in the following claims should not beconstrued to limit the invention to the specific embodiments disclosedin the specification unless the above-detailed description explicitlydefines such terms. In addition, the inventors contemplate variousaspects of the invention in any number of claim forms. Accordingly, theinventors reserve the right to add claims after filing the applicationto pursue such additional claim forms for other aspects of theinvention.

What is claimed is:
 1. A lens system comprising: a lens assembly havinga lens support and a lens carried by the lens support; a fittingmountable to a camera; and a resiliently flexible body extending betweenthe lens assembly and the fitting, the fitting being the sole supportfor the body relative to the camera, the body being configured toposition the lens among at least two operative positions relative to thecamera when the fitting is mounted to the camera, and wherein the bodyhas a rest position to which it at least approximately returns afterbeing moved away from the rest position and released.
 2. The system ofclaim 1, further comprising an f-stop carried by the body.
 3. The systemof claim 1, further comprising a focusing collar coupled to the body. 4.The system of claim 1, in which the resiliently flexibly body isstructured to compress to allow the lens to be moved toward the fittingwhen the lens is manually forced toward the fitting from the restposition.
 5. The system of claim 1, in which the resiliently flexiblybody is structured to extend to allow the lens to be moved away from thefitting when the lens is manually forced away from the fitting from therest position.
 6. The system of claim 1, in which light is capable ofpassing through the lens and at least a center portion of the fittingwhen the resiliently flexible body is in the rest position.
 7. Thesystem of claim 1, in which the resiliently flexible body is structuredto hold the lens assembly relatively perpendicular to the camera whenthe flexible body is in the rest position.
 8. A lens system comprising:a lens; a fitting mountable to a camera; a resiliently flexible bodyextending between the lens and the fitting, the fitting being the solesupport for the body relative to the camera, the body being configuredto position the lens among at least two operative positions relative tothe camera when the fitting is mounted to the camera, wherein the bodyincludes a tubular segment and a lens support, the lens being coupled tothe body by the lens support, at least one portion of the lens supportbeing received by the tubular segment of the body and being movablerelative to at least a portion of the tubular segment of the body, inwhich the lens support includes a tubular frustoconical lens supporthaving a first part and second part, the first part being coupled to thebody and at least one portion of the second part being received by theat least one portion of the body that is tubular, the lens being coupledto the second portion of the lens support.
 9. The system of claim 8 inwhich at least one portion of the second part of the tubularfrustoconical lens support having a smaller cross-sectional area than atleast one portion of the first part of the tubular frustoconical lenssupport.
 10. The system of claim 8, in which the resiliently flexiblebody is structured to compress to allow the lens to be moved toward thefitting when manually forced from the rest position.
 11. The system ofclaim 8, in which the resiliently flexible body is structured to extendto allow the lens to be moved away from the fitting when manually forcedfrom the rest position.
 12. The system of claim 8, in which light iscapable of passing through the lens and at least a center portion of thefitting when the resiliently flexible body is in the rest position. 13.The system of claim 8, in which the resiliently flexible body isstructured to hold the lens assembly relatively perpendicular to thecamera when the flexible body is in the rest position.
 14. A lens systemcomprising: a lens assembly structured to accept a lens therein; afitting mountable to a camera; and a resiliently flexible body extendingbetween the lens assembly and the fitting, the fitting being the solesupport for the body relative to the camera, the resiliently flexiblebody being configured to position the lens among at least two operativepositions relative to the camera when the fitting is mounted to thecamera, the resiliently flexible body having a rest position to which itapproximately returns when manual force is removed from the body, andthe resiliently flexible body having a strength sufficient to hold thelens assembly approximately perpendicular to the camera when theresiliently flexible body is in the rest position.
 15. The system ofclaim 14, further comprising an f-stop carried by the body.
 16. Thesystem of claim 14, further comprising a focusing collar coupled to thebody.
 17. The system of claim 14 in which the lens includes a firstlens, and in which the system further comprises at least one second lenscoupled to the body.
 18. The system of claim 14 in which at least oneportion of the body is tubular.
 19. The system of claim 14 in which atleast one portion of the body is tubular, and in which the systemfurther comprises a tubular frustoconical lens support having a firstpart and second part, the first part being coupled to the body and atleast one portion of the second part being received by the at least oneportion of the body that is tubular, the lens being coupled to thesecond portion of the lens support.
 20. The system of claim 14 in whichthe body is couplable to at least one optical device.
 21. The system ofclaim 14 in which the fitting is mounted to a camera.